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The Center for Astrophysics | Harvard & Smithsonian
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Quasars & Other Active Black Holes

Nearly every galaxy harbors at least huge black hole. The powerful gravity from some of those black holes create powerful storms of matter and light, to the point where they outshine their host galaxies and can be seen from billions of light-years away. These black holes include the some of the brightest single objects in the whole universe, and are called “quasars”, “active galactic nuclei”, and other names that describe their appearance to observers.

 

Our Work

Center for Astrophysics | Harvard & Smithsonian scientists study many aspects of AGNs using a variety of techniques:

  • Using the Event Horizon Telescope (EHT) to study material falling into the supermassive black hole in the galaxy M87. By combining the observing power of telescopes across the globe, EHT captured the first image of matter swirling very close to a black hole, providing new detailed measurements of its behavior.
    CfA Plays Central Role In Capturing Landmark Black Hole Image

  • Studying gamma rays emitted by AGN jets, including those produced by blazars, the most intense supermassive black holes. While most gamma radiation is blocked by air molecules, the Very Energetic Radiation Imaging Telescope Array System (VERITAS) is a set of four 12-meter telescopes designed to see the cascade of light produced when a high-energy gamma ray enters Earth’s atmosphere.
    VERITAS Observes Distant Blazar

  • Surveying quasars to map the very distant universe. The Baryon Oscillation Spectroscopic Survey (BOSS) is an ongoing project to map galaxies and active galactic nuclei, to improve our techniques of measuring cosmic distances, as well as to understand the accelerated expansion of the universe.
    Astronomers Release the Largest Ever Three-Dimensional Map of the Sky

  • Observing AGNs in light from across the entire spectrum, from radio waves to X-rays. These different types of light reveal different aspects of the matter swirling around the black hole, which spans temperatures from close to absolute zero up to millions of degrees.
    Outflowing Gas from Galaxy Supermassive Black Hole Nuclei

  • Using NASA’s Chandra X-ray Observatory and other X-ray telescopes to study the powerful emissions from the innermost regions of quasars and other AGNs. These emissions come from hot matter churning around black holes, along with the intense magnetic fields they produce. The Chandra observatory is able to measure these X-rays to high precision, providing information about the behavior of matter very close to the black hole.
    Record-Setting X-ray Jet Discovered

The Engines of Gravity

Astronomers have found supermassive black holes in most galaxies. These weigh in at millions or billions of times the mass of the Sun, but only a few  of them are “active” at any one time. To be an active galactic nucleus (AGN), the black hole has to collect a lot of gas around it, where it heats up and glows brightly. In some cases, the black hole also generates huge jets of matter, which stream out at nearly the speed of light. Some jets stretch several times farther than the size of the host galaxy.

What an AGN looks like in our telescopes depends on the angle we’re viewing it. For instance, if the jet is pointing more or less toward Earth, the AGN will appear very bright, even outshining the host galaxy. In those cases, astronomers call the AGN a “quasar” or “blazar”. If the jets aren’t pointing toward Earth or the black hole doesn’t produce jets, the AGN might still be bright, but take on a different look. When the bulk of the galaxy is between us and the black hole, it is only visible in X-ray or infrared light, creating an entirely different appearance. These other AGN are known variously as Seyfert galaxies, radio galaxies, and many other names, depending on their particular appearances in observations.

hot gas ejected by a supermassive black hole

Jets of hot gas are ejected by the supermassive black hole at the center of the galaxy Cygnus A. This image shows the galaxy in radio waves (red color), X-rays (blue), and visible light (yellow), revealing how black holes shape their galactic environment.

X-ray: NASA/CXC/SAO; UV: NASA/JPL-Caltech; Optical: NASA/STScI; IR: NASA/JPL-Caltech

What We Hope to Find

The brightest AGNs can be trillions of times the brightness of the Sun, so they serve as cosmic beacons when mapping the structure of the universe on the largest scales. However, astronomers also study AGNs as important objects in themselves, to understand how black holes power the jets and the orbiting donuts of hot gas known as accretion disks, which make them so bright. The powerful flows of matter from AGNs can shut down star formation through the whole galaxy.

The evolution of galaxies and their supermassive black holes are closely linked. Most AGNs are in distant galaxies, and some quasars are in galaxies that formed very early in the history of the universe. Meanwhile, nearby supermassive black holes are typically less active, including the Milky Way’s. AGN jets and other outflows are also responsible for spreading material through galaxies and galaxy clusters, which changes the chemistry of their environments. These jets also illuminate the material between galaxies, which would otherwise be invisible.

the active galaxy Centaurus A

The supermassive black hole at the center of the active galaxy Centaurus A produces the bright jets seen here, measured to move at half the speed of light. The image combines submillimeter light (orange color), X-rays (blue), and visible light.

X-ray: NASA/CXC/CfA/R.Kraft et al.; Submillimeter: MPIfR/ESO/APEX/A.Weiss et al.; Optical: ESO/WFI
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Atomic and Molecular Physics, High Energy Astrophysics, Optical and Infrared Astronomy, Radio and Geoastronomy, Solar, Stellar, and Planetary Sciences, Theoretical Astrophysics, Harvard University Department of Astronomy, Science Education Department, Central Engineering, Director's Office, Chandra X-ray Center, Institute for Theoretical Atomic Molecular and Optical Physics, Institute for Theory and Computation
AstroAI is a institute dedicated to the development of artificial intelligence to enable next generation astrophysics at the Center for Astrophysics | Harvard & Smithsonian. Learn More
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GMACS

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GMACS - Moderate Dispersion Optical Spectrograph for the Giant Magellan Telescope is a powerful optical spectrograph that will unlock the power of the Giant Magellan Telescope for research ranging from the formation of stars and planets to cosmology.

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James Webb Space Telescope Advanced Deep Extragalactic Survey (JADES)

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Sensing the Dynamic Universe

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SDU Website
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Sloan Digital Sky Survey (SDSS)

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The Star Formation Reference Survey

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Telescopes and Instruments

1.5-meter Tillinghast (60-inch) Telescope

The 1.5-Meter (60 Inch) Tillinghast Telescope is a general purpose visible-light telescope located at the Fred Lawrence Whipple Observatory (FLWO) in southern Arizona, operated by the Center for Astrophysics | Harvard & Smithsonian. Astronomers use this telescope to measure the spectrum of light emitted by a wide variety of objects in the Solar System, the Milky Way, and in distant galaxies.

CfA Operated (OIR) | Open to CfA Scientists | Active

Visit the 1.5 Meter (60 Inch) Tillinghast Telescope Website
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See Arcus Website 
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Chandra

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Visit the Chandra Website
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Einstein Observatory

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Spitzer Space Telescope

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Uhuru

The Uhuru X-ray Explorer Satellite was the first spacecraft dedicated to X-ray astronomy. During its mission in the early 1970s, Uhuru mapped the X-ray sky. It provided the first observational evidence for black holes, revealed that galaxy clusters contain hot X-ray-emitting gas, and charted the behavior of neutron stars in binary systems. The observatory was named Uhuru, the Swahili word meaning “freedom”, in honor of Kenyan independence and because the rocket carrying the spacecraft was launched into orbit from a site off the coast of Kenya near Mombasa. The success of the Uhuru satellite led the way for all subsequent space telescopes, from the Einstein Observatory to NASA’s flagship Chandra X-ray Observatory.
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